wireless power/energy analysis tool nswc crane with user ... · distribution statement a –...
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Distribution Statement A – Approved for public release.
CAPT JT Elder, USNCommanding Officer
NSWC CraneWireless Power/Energy Analysis Tool with User Interface
Presented By: Dr. Corey A.M. Bergsrud and Mr. Alex ZellnerDate: May 25, 2017
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Dr. Brett Seidle, SESTechnical Director
NSWC Crane
Distribution Statement A – Approved for public release.
Wireless Power/Energy Analysis Tool with User Interface
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NOTE Naval Innovation Science and Engineering (NISE/219) funding
Internal Rapid Experimentation (IRE)
Wireless Power Analysis Diode Analysis
Distribution Statement A – Approved for public release.
Why Develop Tool?
• Simplify and streamline initial wireless power/energy parametric analysis– Saves effort, time, and money– Aid in teaching/learning
• Standardize procedure– Consistency amongst research community
• Avoids ambiguity• Reduces possible errors
• Base tool allows for evolving multi-purpose platform– New measured data– Incorporate other relevant systems/information
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Distribution Statement A – Approved for public release.
How Develop Tool?
• Formulas– N. Shinohara [1]; W. Brown and E. Eves [2].
• Closed form equations– J. McSpadden, L. Fan, and K. Chang [4]; T.-W. Yoo and K.
Chang [7]; Y.-J. Ren and K. Chang [8]; C. Valenta, M. Morys, and G Durgin [11].
• Measured data– W. Brown [3]; J. McSpadden, L. Fan, and K. Chang
[4]; P. Koert, J. Cha, and M. Macina [5].
• Creativity
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Distribution Statement A – Approved for public release.
Wireless Power Analysis GUI
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Distribution Statement A – Approved for public release.
Default GUI: Wireless Power Analysis
6Input Variables
Parametric Analysis Graphs
Output Variables
Tabs Link to instructions
Distribution Statement A – Approved for public release.
WPA Features 1: Tabs & Inputs
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Distribution Statement A – Approved for public release.
WPA Features 2: Inputs
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Distribution Statement A – Approved for public release.
WPA Parametric Analysis
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Dependent Variables
Aperture-to-aperture transmission
efficiency
Distribution Statement A – Approved for public release.
WPA Features 3: Outputs
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Rectenna RF-to-DC Conversion Efficiency
Collection Efficiency
Atmospheric Efficiency
Analysis Summary
DC Power Output
Distribution Statement A – Approved for public release.
WPA Example 1
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Distribution Statement A – Approved for public release.
EX: 1.1
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Tracking Dots
Apertures
Populating
Distribution Statement A – Approved for public release.
EX: 1.2
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(1) Second Data Point
(2) Waiting for input
(3) To get outputCopies over fixed data
Distribution Statement A – Approved for public release.
EX: 1.3
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Generates Plot GraphDependent Variable
Independent Variable
Distribution Statement A – Approved for public release.
WPA Example 2
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Distribution Statement A – Approved for public release.
EX: 2.1
16Reset All
Distribution Statement A – Approved for public release.
EX: 2.2
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Tracking Dots
Distribution Statement A – Approved for public release.
EX: 2.3
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WARNING: One or more variables are out of bounds!
Tracking Dots?
Distribution Statement A – Approved for public release.
Diode Analysis GUI
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“The first component to consider is the nonlinear Schottky diode since the designof the other Rectenna parts depends directly upon the diode’s performance [6].”
Distribution Statement A – Approved for public release.
Default GUI: Diode Analysis
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Distribution Statement A – Approved for public release.
Example Diode Component
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Enter Diode SPICE parameters
Voltage across the diode limitation
Max dc power limitation
Distribution Statement A – Approved for public release. 22
THANK YOU FOR YOUR TIME & ATTENTION
Blimp
Satellites
Sea Port
Aircraft
Helicopter
Rover
Earth-to-Earth
[12]
[13]
[14]
[15]
[16]
[17]
[18]
[19]
Distribution Statement A – Approved for public release.
References• [1] N. Shinohara, “Beam efficiency of wireless power transmission via radio waves from short range to long range,”
Journal of the Korean Institute of Electromagnetic Engineering and Science, VOL. 10, NO. 4, DEC. 2010.
• [2] W. C. Brown and E. E. Eves, “Beamed microwave transmission and its application to space,” IEEE Trans. On Microwave Theory and Techniques, VOL. 40, NO. 6, 6, JUNE 1992.
• [3] W.C. Brown, "Electronic and Mechanical Improvement of the Receiving Terminal of a Free-Space Microwave Power Transmission System", Raytheon Company, Wayland, MA, USA, Tech. Rep. PT-4964, Aug. 1977, NASA Rep. CR-135194.
• [4] J.O. McSpadden, L. Fan, and K. Chang, "Design and experiments of a high-conversion-efficiency 5.8-GHz rectenna," IEEE Trans. MTT, vol. 46, no. 12, pp. 2053-2060, Dec. 1998.
• [5] P. Koert, J. Cha, and M. Macina, "35 and 94 GHz rectifying antenna systems," in SPS 91-Power From Space Dig., Paris, France, Aug. 1991, pp. 541-547.
• [6] B. Strassner and K. Chang, “Microwave power transmission: historical milestones and system components,” Proc.of the IEEE, VOL. 101, NO. 6, June 2013.
• [7] T.-W. Yoo and K. Chang, “Theoretical and experimental development of 10 and 35 GHz rectennas,” IEEE Trans. MTT, VOL. 40, NO. 6, June 1992.
• [8] Y.-J. Ren and K. Chang, “5.8-GHz circularly polarized dual-diode rectenna and rectenna array for microwave power transmission,” IEEE Trans. MTT, VOL. 54, NO. 4, April 2006.
• [9] C. R. Valenta and G. D. Durgin, “Harvesting wireless power,” IEEE microwave magazine, pp. 108-120, June 2014.
• [10] A. Collado and A. Georgiadis, “Optimal waveforms for efficient wireless power transmission,” IEEE Microw. Wireless Compon. Lett., vol. 24, no. 5, pp. 354-356, May 2014.
• [11] C. R. Valenta, M.M. Morys, and G. Durgin, “Theoretical energy-conversion efficiency for energy-harvesting circuits under power-optimized waveform excitation,” IEEE Trans. MTT, VOL. 63, NO. 5, May 2015.
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Distribution Statement A – Approved for public release.
References• [12] URL:
https://www.bing.com/images/search?view=detailV2&ccid=vohZqWL8&id=9195FDD41330E339C96112D48F45752F6F1CDF31&thid=OIP.vohZqWL8AXYZL4qB8YlTlAEUDE&q=ground+to+ground+wireless+power+transfer&simid=608030773458898868&selectedIndex=26&ajaxhist=0
• [13] W. C. Brown, “The technology and application of free-space power transmission by microwave beam,” Proc. Of the IEEE, Vol. 62, No. 1, January 1974.
• [14] Y. Fuse, T. Saito, S. Mihara, K. Ijichi, K. Namura, Y. Honma, T. Sasaki, Y. Ozawa, E. Fujiwara, and T. Fujiwara, “Outline and progress of the Japanese microwave energy transmission program for SSPS,” Proc. IMWS-IWPT, 20111
• [15] N. Shinohara, “Beam control technologies with a high-efficiency phased array for microwave power transmission in Japan,” Proc. Of the IEEE, VOL. 101, No. 6, June 2013.
• [16] URL: https://www.bing.com/images/search?view=detailV2&ccid=xzkf3hdL&id=89B5EF367CF0F10C0790356769583C480FE6C0A8&thid=OIP.xzkf3hdLALYUlZHZg5UfcQEsDV&q=wireless+power+japan%2c+milax&simid=608034145008094235&selectedIndex=20&ajaxhist=0
• [17] P. Schubert, IUPUI.
• [18] C. Bergsrud and J. Straub, “A space-to-space microwave wireless power transmission experiential mission using small satellites,” Acta Astronautica 103, pp. 193-203, 2014
• [19] G. Templeton, Japan’s 25-year plan to put a gigawatt solar power farm in space, April 28, 2014. URL: https://www.extremetech.com/extreme/181389-japans-25-year-plan-to-put-a-gigawatt-solar-power-farm-in-space
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